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By James Gallagher Health and Science reporter, BBC News
Scientists believe they are closer to being able to change the DNA of wild mosquitoes in order to combat malaria.
In the laboratory, they made a gene spread from a handful of mosquitoes to most of the population in just a few generations, according to a report in Nature.
If the right gene can be made to spread then researchers hope to reduce the number of cases of malaria.
Other academics have described the study as a “major step forward”.
The World Health Organisation estimated that malaria caused nearly one million deaths in 2008.
Spreading resistance
Around a million people are thought to die from malaria each year
The research, however, has a great challenge – getting those genes to spread from the genetically-modified mosquitoes to the vast number of wild insects across the globe.
Unless the gene gives the mosquito an advantage, the gene will likely disappear.
Scientists at Imperial College London and the University of Washington, in Seattle, believe they have found a solution.
They inserted a gene into the mosquito DNA which is very good at looking after its own interests – a homing endonuclease called I-SceI.
The gene makes an enzyme which cuts the DNA in two. The cell’s repair machinery then uses the gene as a template when repairing the cut.
As a result the homing endonuclease gene is copied.
It does this in such a way that all the sperm produced by a male mosquito carry the gene.
So all its offspring have the gene. The process is then repeated so the offspring’s offspring have the gene and so on.
In the laboratory experiments, the gene was spread to half the caged mosquitoes in 12 generations.
Defeating malaria
Professor Andrea Crisanti, from the department of life sciences at Imperial College London, said: “This is an exciting technological development, one which I hope will pave the way for solutions to many global health problems.
“At the beginning I was really quite skeptical and thought it probably would not work, but the results are so encouraging that I’m starting to change my mind.”
He said the idea had been proved in principle and was now working on getting other genes to spread in the same way.
He believes it could be possible to introduce genes which will make the mosquito target animals rather than humans, stop the parasite from multiplying in the insect or produce all male offspring which do not transmit malaria.
Professor Janet Hemingway, from the Liverpool School of Tropical Medicine, said the work was an “exciting breakthrough”.
She cautioned that the technique was still some way off being used against wild mosquitoes and there were social issues around the acceptability of using GM technology.
“This is however a major step forward providing technology that may be used in a cost effective format to drive beneficial genes through mosquito populations from relatively small releases,” she added.
Dr Yeya Touré, from the World Health Organisation, said: “This research finding is very important for driving a foreign gene in a mosquito population. However, given that it has been demonstrated in a laboratory cage model, there is the need to conduct further studies before it could be used as a genetic control strategy
Scientists call for more research, conservation of trees to harvest potential for next generation of malaria drugs
A scientist holding Warburgia ugandensis plant (world Agroforestry Center)
NAIROBI (21 April 2011)— Research released in anticipation of World Malaria Day finds that plants in East Africa with promising antimalarial qualities—ones that have treated malaria symptoms in the region’s communities for hundreds of years—are at risk of extinction. Scientists fear that these natural remedial qualities, and thus their potential to become a widespread treatment for malaria, could be lost forever.
A new book by researchers at the World Agroforestry Centre (ICRAF) and the Kenya Medical Research Institute (KEMRI), Common Antimalarial Trees and Shrubs of East Africa, provides a detailed assessment of 22 of the region’s malaria-fighting trees and shrubs. While over a thousand plant species have been identified by traditional healers as effective in the prevention or treatment of malaria symptoms, the species in the book were assigned by both traditional medicinal practitioners and scientists as those that have potential for further study.
According to researchers, many species of trees in East Africa are at high risk of extinction due to deforestation and over-exploitation for medicinal uses. Scientists in the field have been able to identify at-risk tree species, including those that have antimalarial qualities, by monitoring deforestation in the region and by talking to herbalists and local communities. According to researchers, not all species of antimalarial trees are at risk, particularly those that grow wild in lowland and coastal areas.
ICRAF is doing its part preserving these trees and shrubs by holding samples of most of the species with antimalarial qualities in its genebank and growing these trees in plant nurseries at its headquarters in Nairobi. The ICRAF genebank holds close to 200 species, of which at least 30 are known to have antimalarial properties.
The field data was gathered by ICRAF scientists conducting research across Kenya, Uganda, and Tanzania, where they met with approximately 180 herbalists and 100 malaria patients in 30 separate communities. KEMRI supported the process by supplying the information about each plant’s chemical compound make-up—research that is the result of a sophisticated laboratory process developed by KEMRI for testing natural products.
“We’ve only scratched the surface on the potential value of these plants. Although widely used by farmers and people in rural communities, most of this information has never been collected in a comprehensive way by researchers,” said Dr. Geoffrey Rukunga, Director of KEMRI’s Centre for Traditional Medicine and Drug Research and one of the book’s co-authors. “Going forward, I’d like to see more investment and more research on the power of these plants to fight the scourge of malaria and other diseases.”
One of the drugs most widely used historically to treat malaria, quinine, was derived from the bark of the Cinchona tree in South America. Today, the world’s newest, most-effective therapeutic treatment for malaria also comes from a plant, the Artemisia annua shrub. However, access to malaria therapies based on artemisinin compounds remains low—around 15 percent in most parts of Africa and well below the World Health Organizations’ 80 percent target.
Additionally, the malaria parasite’s ability to resist artemisinin is already beginning to emerge in Southeast Asia. This comes years after the World Health Organization labeled the spreading resistance of malaria to cheap and widely available drugs such as chloroquine and sulfadoxine-pyrimethamine as a major public health problem. The increasing failure of once-effective malaria drugs has added urgency to the search for promising new targets.
Malaria still kills some 800,000 people per year, the majority of whom are children under five years of age in sub-Saharan Africa. A lack of access to doctors and drugs leaves many communities in Africa with few alternatives other than looking for natural remedies to address symptoms of malaria, including high fever, severe headaches, bone aches, nausea and vomiting.
“We’re not saying that using these medicinal plants is a replacement for common prevention treatments like bed nets or effective medicines like ACT,” said Dr Najma Dharani, a Consultant Research Scientist at the ICRAF in Nairobi, Kenya, who led the field research portion of the study. “But we believe that it’s worth learning from communities that have been treating malaria symptoms with plants for hundreds of years. We need to do more research because one of these plants could prove to be the next Artemisia, and we need to do our best to preserve the plants that are going extinct.”
Indeed, without clear research or proper guidance for their sustainable use, many of the plants with medicinal properties are being over-exploited and are in danger of extinction. One such plant, which is critically endangered in Kenya and threatened in other regions, is Zanthoxylum chalybeum, commonly known as “Knobwood.” It grows in dry woodlands or grasslands of eastern and southern Africa and has been found to have antimalarial properties that need to be further explored. An extraction process from leaves, bark or root is used to effectively treat a malarial fever in many communities. Other uses for the plant include infusing tea with the leaves, making toothbrushes, and using the seeds as beads in traditional garments.
The African wild olive (Olea europaea Africana), also threatened in East Africa due to over-exploited for timber, contains organic extracts with significant levels of antimalarial activity, and is used to treat malarial and other fevers. The plant also acts as a natural laxative to expel parasites or tapeworms.
“Throughout my eight years of research in Africa, I have seen that we have an entire pharmacy in our farms and in our forests. We have plants that should be used by scientific companies to develop more options for malaria drugs,” said Dr. Dharan. “And we cannot become complacent and rely on one herb, because we’ve learned that developing resistance is likely.”
Beyond the complicated process to extract and test antimalarial compounds from these trees, scientists have struggled to track or replicate the treatment process as it occurs in communities. Besides the plant itself, there may be other factors contributing to a malaria patient’s recovery. For example, a healer may combine one plant with another that changes its chemical compound and boosts its effectiveness. Unless more is done to understand these processes in the field, scientists in laboratories and researchers at major drug companies will lose that knowledge.
“While we’ve made scientific progress identifying these compounds over the last few years, the fact is that we may lose these important trees before we’ve had a chance to understand their ability to defend us against malaria, a disease that devastates Africa—killing hundreds of thousands of our children and costing us billions of dollars in productivity year after year,” said Dr. Rukunga. “We need to approach this as an opportunity on multiple fronts: to preserve the biodiversity that may hold the next cure, to strengthen the research done on the ground in communities, and to continue our diligent work testing our natural resources in the lab.”
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The World Agroforestry Centre (ICRAF) is an autonomous, non-profit research organisation whose vision is a rural transformation in the developing world resulting in a massive increase in the use of trees in rural landscape by smallholder households for improved food security, nutrition, income, health, shelter, energy and environmental sustainability. The Centre generates science-based knowledge about the diverse roles that trees play in agricultural landscapes, and uses its research to advance policies and practices that benefit the poor and the environment. We are one of the 15 centres of the Consultative Group on International Agricultural Research (the CGIAR). http://www.worldagroforestrycentre.org/
The Kenya Medical Research Institute(KEMRI) was established in 1979 as the national body responsible for carrying out health science research in Kenya. Since then, KEMRI has served as a centre of excellence for health research in Africa. It works closely with the Kenyan Ministry of Health and various national councils and committees on issues of policy and priorities. The institute accomplishes its mandate through research centres that are intended to focus on certain specific areas of national and/or strategic importance. The centre that conducts research on herbal medicines is the Centre for Traditional Medicine and Drug Research (CTMDR). This centre studies the chemical composition, efficacy and safety of traditional medicines, and the socio-cultural and anthropological basis of the use of herbal remedies. http://www.kemri.org/
One of the most exciting and complicated field of science is the study of the human brain. Recent research indicates that an individual is only able to fully utilize half of one percent of the brain’s capacity in his or her lifetime. Undoubtedly, the dynamics of the human brain remains a mystery to scientists.
The human brain
The report above reveals to a large extent the under utilization of the brain by humans which can be attributed to the frailty of the human species. Taking time to reflect on this should spark in you a desire to make the best use of this wonderful gift bestowed on the human race. Imagine the ‘brains’ behind the various inventions in the world of science and technology: computers, security gadgets, electronics, automobiles, nuclear weapons, medicine and so on. Despite these marvelous achievements in this jet age, it is challenging to know that just one percent of the brain’s capacity is utilized. So, we need to ask ourselves individually: am I fully utilizing the capacity of my brain? If measured after my demise, can it be said that I was able to use up to half of the one percent of my brain?
The Human brain is distinct in its design and makeup to that of other creations such as animals. As humans, our brain makes us reason on questions such as; WHY ARE WE HERE AS HUMANS; WHAT IS THE PURPOSE OF LIFE; WHY DO WE DIE AND SUFFER AS HUMANS; DOES GOD REALLY EXIST? These questions and so many more are out of reach of the animal brain. Fundamentally, we as humans are created as ‘free moral agents’, whereas, animals are created to be guided by instincts. As free moral agents, we have the capacity to make decisions on our own without external influence, to be conscious of our actions either for good or bad, and to satisfy our spiritual desires all of which animals do not possess.
In what practical ways then can the human brain be put to its best use? I want to share three ways we can make the best use of the human brain.
The first way is what I will identify as ADEQUATE REST. The human brain as part of the human body needs adequate rest to be able to function properly. Many an individual takes this serious matter with levity or display a nonchalant attitude. Scientist have suggested that on the average, the human brain should be made to relax for about seven to eight hours especially during night rest when the brain is able to better coordinate its millions of neuron cells for full utilization. Due to the demands of modern society, many people hardly give adequate rest to the brain which in scientific terms represents an individual. People work from morning all through the night with little or no rest. Imagine one in such a situation tasking the brain with less than five hours rest per day, all through the year!! That is not only an abuse of this great ‘asset’, but also suicidal to such individual. Hence, it is vital to give the brain as much rest as possible on daily basis for its full potentials to be annexed by its host. This should not be left to chance; it is a must-do affair for our personal and social development.
The second way the brain can be best utilized is PRODUCTIVE THINKING AND MEDITATION. Thinking is the seed that germinates into an idea, which grows into innovation. Thinking in this context is not one that results out of our daily concerns and anxieties such as how to meet ends needs, how to meet deadlines on the job, or how to solve a personal or family challenge. However, productive thinking and meditation is one undertaken by an individual sometimes for days, months and even years to address or proffer lasting solution to societal problems or improve the quality of human life. Such productive thinking and meditation are responsible for the innovation of airplanes by Wright Brothers, Isaac Newton’s law of gravitational force, and so many others that have contributed significantly to human development especially in the areas of science and technology. Are such accomplishments out of the reach of anyone who desires them? Hardly will I say yes.
As individuals, it is imperative we conduct an honest appraisal on how we put our brain to use through productive thinking and meditation. Therefore, there is need for us task our brain productively. This we can do by taking time off maybe an hour or less in a day, if we appear too busy all the week, maybe an hour or two over the weekend to think and meditate productively on an area of human interest that needs to be addressed or improved upon. This will be made much easier if this productive meditation is done in line with an individual’s area of interest or strength in life. In other words, if your area of interest in life is in sciences, ask yourself; what aspects of my profession need to be improved upon? In what practical ways can I proffer lasting solutions to the identified challenges in my career? Care must be taken however, not to engage the brain for productivity when it’s not naturally inclined to be. There are moments the brain undergoes some processes unknown to an individual. Any attempt to engage the brain productively at such time will bear no fruit. Hence, draw up a number of problems you can identify around your area of specialization and take a quality time to meditate productively with the convenience of the brain in your quest to invent a lasting solution to the problem. Decades ago, malaria and Polio were thought to be ailments that had come to stay with humanity. Thanks today for the brains in medical science that have proffered lasting solutions to these deadly ailments especially in children. A good sanitary environment and effective anti malaria/Polio vaccines are available as remedies.
Finally, the brain can be put to good use through HEALTHYSOCIAL INTERACTION. By this, I mean the ability of an individual to effectively interact in all spheres of human life. This includes but not limited to the academics, social clubs, religion, professional career, associations and so more. When an individual is actively involved in one or more of these forums, the brain is intellectually engaged and this aids its development. The academia for example assists an individual to interact with like-minded people in the pursuit and advancement of a given profession. Such interaction involves making extensive researches, conducting surveys, amongst others. This puts the brain to good use and help in its development.
Therefore, I challenge all you readers of this piece who are yet to be conscious of the need to fully utilize the brain as addressed above to start the exercise. The brain is just like a tool that needs constant usage under favorable environment to work properly or be productive. When a tool such as a cutlass is not utilized by a farmer for days or months, it naturally starts deteriorating. The same principle applies with equal force to the human brain. By putting the three workable suggestions above to use, you might just be positioned to be the next person whose name appears on the Guinness world Book of records for your creativity and ingenuity.
Human speech originated in central and southern Africa, according to new research on languages. It is then said to have spread around the globe alongside migrating human populations.
A comprehensive study of phonemes, or the perceptually distinct units of sound that differentiate words, used in 504 human languages reveals that the dialects containing the most phonemes are spoken in Africa, those with the fewest in South America and on tropical islands in the Pacific Ocean.
This pattern of phoneme usage around the world mirrors the pattern of human genetic diversity, which also declined as humans expanded their range from Africa to colonize other regions, reveals an analysis in the 15 April issue of Science
Data compiled by Quentin Atkinson from the University of Auckland, shows a movement of languages out of the African continent to other areas of the world. Atikson says, “It seems like the obvious explanation is that people carried language – along with their genes – with them as they expanded out of Africa.”
Atkinson’s findings further reveal that areas that were most recently colonised adapt fewer phonemes into their local languages while regions that have hosted human life for a long time still use the most phonemes, sub-Saharan Africa in particular.
According to Atkinson’s study, the highest levels of phonemic diversity are found in language families associated with the people of Southeast Asia. His research frames comple language as one of the earliest archaeological symbols of mordern human culture, indicating that it was a key cultural innovation that ultimately led to our colonisation of the globe.
In conclusion Atkinson says: “Modern humans are just one big, genetic family with a single common ancestor, one of the things I like about these results is that, to the extent that language is an identity, we all seem to be part of one big, cultural family as well.”
A team of graduate students has created a new smartphone application they say will allow healthcare workers in remote locations to diagnose malaria cases on the spot.
But first, the students hope their application wins this weekend’s Imagine Cup 2011 national finals in Seattle.
The 9th-annual Imagine Cup, sponsored by Microsoft, asks student entrants to “imagine a world where technology helps solve the toughest problems.”
Tristan Gibeau, 25, a graduate computer engineering student at the University of Central Florida in Orlando, said his team’s application fits the bill.
“It’s going to make a difference in trying to contain the outbreak of malaria,” said Gibeau, the project’s software designer.
“In the big picture, it’ll hopefully help in the fight against most diseases out there and make everybody’s life a little easier.”
His team’s prototype is a Windows 7-equipped Samsung Focus smart phone modified with a microscopic camera lens.
Gibeau said the software application can take a picture of a blood sample, process the data to detect malaria parasites, quantify how much malaria is in the sample and point the parasites out to the phone user.
“It actually draws a red box around the clusters of malaria, and it actually notifies you how many it found,” Gibeau said.
Although microscopic lenses are already available for smart phones, Gibeau said the software takes the concept’s usefulness to another level.
It would enable a doctor or nurse working, for example, in an African village lacking Internet access to make a diagnosis without having to upload data for processing elsewhere.
However, once the data stored in the phone is uploaded, it can be used to spot disease trends, Gibeau said.
He said he is working on smart phone applications to detect sickle cell and other diseases and also plans to make the software easily adaptable to lab-based microscopes.
The smart phone application was the idea of team member Wilson To, a 25-year-old graduate student in comparative pathology at the University of California at Davis.
It builds upon a mobile microscope concept that To and a different team created to win last year’s Imagine Cup national finals.
Gibeau said the team is working toward patenting and marketing the new application.
“From different conversations we’ve had with investors, we feel that this definitely is a money-maker,” he said.
Global health experts said on Thursday that the world’s most powerful drugs are losing the battle against drug-resistant strains of malaria, HIV, gonorrhea and tuberculosis
According to Dr. Thomas Frieden, director of the Centers for Disease Control and Prevention, antimicrobial resistance is robbing us of the certainty that antibiotics will always be there to fight infections and new drug-resistant pathogens are emerging. “It’s not enough to hope that we’ll have effective drugs to combat these infections. We must all act now to safeguard this important resource,” Frieden said
What you need to know about Anti-Microbial Resistance
What is Anti-Microbial Resistance:
Antimicrobial resistance occurs when germs change in a way that reduces or eliminates the effectiveness of drugs to treat them. This happens when antibiotics, antivirals, antifungals and other medications are used too liberally. About half of antimicrobial drugs — antibiotics in particular — are used unnecessarily or inappropriately prescribed in U.S. hospitals and in doctors’ offices, the CDC says. The best approach to preserving those drugs is to use them only when needed.
How Anti-Microbial Resistance affects developing world, especially Africa
HIV: Studies show that up to 20 percent of newly diagnosed HIV patients have transmitted a drug-resistant infection. Approximately 22 million people live with HIV in Sub-Saharan Africa. In the US and other developed countries, Doctors can test or resistance before prescribing drugs, but such luxury may be too hard to come by in under-privileged communities
Malaria: Plasmodium falciparum, the most dangerous of the malaria parasites, has developed resistance in nearly all areas of the world where it is transmitted. Annually, there are about 225 million malaria infections and nearly 800,000 deaths. Women and children are the most affected, particularly in Sub-Saharan Africa.
Bacteria use for producing anti-body against malaria are seen through a microscope at Westminster University in London, Tuesday, March 15, 2011. In a cramped London laboratory filled with test tubes, bacteria and mosquitoes, scientists are trying to engineer a new weapon in the battle against malaria: a mutant fungus. For years, Angray Kang at Westminster University and colleagues have been testing whether they could genetically tweak a fungus to kill the malaria parasite carried by mosquitoes.
NPR
In a cramped London laboratory filled with test tubes, bacteria and mosquitoes, scientists are trying to engineer a new weapon in the battle against malaria: a mutant fungus.
For years, Angray Kang at Westminster University and colleagues have been testing whether they could genetically tweak a fungus to kill the malaria parasite carried by mosquitoes.
Now they’ve found that in lab experiments, mosquitoes exposed to the fungus show a sharp drop in levels of the parasite. If it works that way in the wild, that should make it harder for the disease to infect people.
Kang said the mutant fungus could be sprayed onto walls and bednets like insecticides and could be made for a comparable cost.
He said the same process of genetic modification could also be used to target other insect-spread diseases like dengue and West Nile virus. The research was done together with scientists at the Johns Hopkins School of Public Health and was funded by the U.S. National Institutes of Health. Early results were published recently in the journal Science.
“This is very exciting research,” said Andrew Read, director of the Center for Infectious Disease Dynamics at Pennsylvania State University. He has worked on similar projects but was not involved with the fungus research. “It tells us that if you can’t find something in nature to do what you want, you can just make it.”
Read said using the souped-up fungus might be less environmentally invasive than other genetic approaches. Some critics have warned that competing biological approaches, like scientists creating mutant mosquitoes, could wreak havoc to ecosystems if billions of the insects are released into the wild.
With the fungus, “you just spray it on the wall and it does its job,” Read said. “You don’t have to worry about generation after generation of the stuff.”
He also said the fungus technology could be a new way of dealing with insecticide-resistant mosquitoes, an increasing problem that has meant the return of effective but controversial sprays like DDT. “With the (mutant) fungi, you wouldn’t have chemical residues hanging around,” he said. “It would just be a fungus very similar to what is already found in nature.”
In laboratory tests, Kang and colleagues found mosquitoes exposed to the mutated fungus had malaria parasite levels about 85 percent lower than normal. When they added a scorpion toxin to the mix, levels dropped by 97 percent. No tests have shown whether using the fungus would curb human malaria cases, but experts think fewer malaria parasites should translate into fewer cases.
“If the strategy works and there are fewer parasites, this could change how malaria is spread and reduce transmission to humans,” said George Christophides, an infection expert at Imperial College London who was not associated with the research.
Kang’s experiment involved inserting a human antibody against malaria into a fungus commonly found in soil and plants worldwide. Spores made by the fungus burrow into the mosquito, invading its circulatory system. When the malaria-causing parasite multiplies inside the insect, the antibody keeps the parasites from reaching the mosquito’s salivary glands. That theoretically stops the disease’s spread.
“The mosquito can be infected by malaria, but it can’t pass it onto humans,” Kang said. The mutated fungus then eats away at the mosquito from the inside, killing the insect after a couple of weeks. That’s long enough for the mosquito to reproduce, which should lessen its incentive to evolve resistance to it.
The same fungus — minus the genetic modifications — is already produced in industrial quantities to squash locust outbreaks in Australia. The fungus is naturally lethal to locusts, so no genetic modification is needed.
If Kang and colleagues can get enough funding, they hope to test the mutant fungus in malaria-endemic countries like Burkina Faso, Kenya or Tanzania.
Other experts doubted whether the laboratory experiment could be replicated in the wild. “It’s a neat scientific idea, but there are questions about (the mutated fungus’s) stability and formulation,” said Janet Hemingway, director of the Liverpool School of Tropical Medicine. She said the mutant fungus would have to survive being shipped to Africa and then be viable for another three to six months in stifling heat once it’s sprayed onto walls or bednets.
One group that campaigns against genetically modified organisms warned the mutant fungus could skew behaviors of other wildlife.
“The release of any genetically modified organism into the environment runs the risk that it may have wider impacts than just its target,” said Pete Riley, campaign director of GM Freeze, a U.K.-based advocacy group. He said the modified fungus could have unintended consequences which might be impossible to reverse. “Nature has a pretty cunning way of getting around everything we throw at it,” he said.
Kang acknowledged that simply having a new mutant fungus would not stop malaria. “We still need better drugs and other interventions,” he said. “But malaria kills about a million people every year so we have to try whatever may work.”
31 March 2011 –Secretary-General Ban Ki-moon today officially opened the new energy-efficient United Nations office complex in the Kenyan capital, Nairobi, calling it a model for environmentally sustainable architecture in Africa and beyond.
“This building is beautiful, comfortable and efficient. But more than any of that, this building is a living model of our sustainable future,” Mr. Ban said at the opening of the facility at Gigiri, which houses the new offices of the UN Environment Programme (UNEP) and the UN Human Settlements Programme (UN-HABITAT).
According to UNEP, buildings are responsible for more than one third of global energy use and are the largest source of greenhouse gas emissions in most countries. The Nobel Prize-winning Intergovernmental Panel on Climate Change estimates that emissions from buildings will rise to 11.1 billion tons by 2020.
The manufacture of building materials contributes a further 4 billion tons of carbon dioxide emissions annually, a figure that is increasing with the continuing rise in construction globally, most of it in developing countries.
“If our growing population is going to survive on this planet, we need smart designs that maximize resources, minimize waste and serve people and communities,” said Mr. Ban. “This facility hits all of these targets.”
From the 6,000 square metres of shimmering solar panels to the environmentally-friendly paint on the walls, the new UN offices – which comprise four buildings that can accommodate 1,200 staff – boast myriad environmental features, while capitalizing on the natural benefits of Nairobi’s climate.
The features of the energy-neutral complex include automated low-energy lighting for workspaces, energy-efficient computers and water-saving lavatories. Rainwater is collected from the roofs to feed the fountains and ponds at the four entrances, and sewage is treated in a state-of-the-art aeration system and recycled to irrigate the landscaped compound.
“This facility embodies the new, green economy I have championed for years now. An economy that can usher in a cleaner future, create jobs and spur economic growth,” said Mr. Ban, who was joined at the inauguration ceremony by Kenyan President Mwai Kibaki, UNEP Executive Director Achim Steiner and UN-HABITAT Executive Director Joan Clos, as well as other UN officials and dignitaries.
Calling the facility a “model for green architecture in Africa and beyond,” Mr. Ban said he hoped all UN offices will reach the very high bar set by those in Nairobi.
He added that the Organization is aiming to make its Headquarters complex in New York, which is currently undergoing major renovations after 60 years of existence, one of the cleanest, greenest buildings in the world.
While in Nairobi, Mr. Ban also held separate meetings with Mr. Kibaki and Prime Minister Raila Odinga. He also had a range of meetings with senior UN officials either based in Nairobi or visiting for the Chief Executives Board (CEB) gathering. That meeting, held twice a year, brings together the heads of the specialized agencies, funds and programmes in the UN system.
Also today, he launched his report on HIV/AIDS ahead of the high-level meeting on the topic at the General Assembly in June.
